CN203086615U

CN203086615U - Stereoscopic displaying apparatus

Info

Publication number: CN203086615U
Application number: CN2012206640277U
Authority: CN
Inventors: 刘美鸿
Original assignee: Shenzhen Estar Displaytech Co
Current assignee: Shenzhen Estar Displaytech Co
Priority date: 2012-12-05
Filing date: 2012-12-05
Publication date: 2013-07-24
Anticipated expiration: 2022-12-05

Abstract

The utility model provides a stereoscopic displaying apparatus, comprising a display; a camera head used for tracking human eye position information; and a processor electrically connected with the camera head and used for generating control signals according to the human eye position information. The display comprises a dynamic raster which is electrically connected with the processor and used for controlling positions of bright and dark stripes in the dynamic raster according to the control signals to enable the positions of the bright and dark stripes in the raster to have adaptive changes so as to be suitable for the positions of human eyes. Thus, light incident on the dynamic raster, after transmitting through light permeable gaps of the dynamic raster, is then incident on displaying pixels of the display, thereby further enabling left eye pixel image light to be incident on the left human eye and enabling right eye pixel image light to be incident on the right human eye. The utility model provides a stereoscopic displaying apparatus, comprising a display; a camera head used for tracking human eye position information; and a processor electrically connected with the camera head and used for generating control signals according to the human eye position information. The display comprises a dynamic raster which is electrically connected with the processor and used for controlling positions of bright and dark stripes in the dynamic raster according to the control signals to enable the positions of the bright and dark stripes in the raster to have adaptive changes so as to be suitable for the positions of human eyes. Thus, light incident on the dynamic raster, after transmitting through light permeable gaps of the dynamic raster, is then incident on displaying pixels of the display, thereby further enabling left eye pixel image light to be incident on the left human eye and enabling right eye pixel image light to be incident on the right human eye.

Description

3 d display device

Technical field

The utility model relates to the Display Technique field, particularly relates to a kind of 3 d display device.

Background technology

In the present grating technology, preparing grating well after, the position of grating light and shade striped will be fixed, this has brought inconvenience for our work, especially when utilizing the parallax barrier technology to realize that stereo-picture shows, because the position of grating light and shade striped is uncontrollable, can only limit spectators' eyes and just can watch the 3D rendering effect in certain particular range, has influenced the application of parallax barrier stereo display technique in life.

Therefore, need provide a kind of 3 d display device to solve the problems of the technologies described above.

The utility model content

The utility model mainly provides a kind of 3 d display device, utilize camera to follow the trail of the human eye positional information, and then utilize control unit to realize that according to position of human eye information the change of stop position is to adapt to two different observation places of people, the effect that 3D rendering is watched in realization.

For solving the problems of the technologies described above, the technical scheme that the utility model adopts is, a kind of 3 d display device is provided, and comprising:

Display;

Camera is arranged on the front end face of display, is used to follow the trail of the human eye positional information;

Processor is electrically connected with camera, is used for generating control signal according to position of human eye information;

Wherein, described display comprises dynamic raster, described dynamic raster is electrically connected with processor, described dynamic raster comprises first glass plate, second glass plate, liquid crystal layer and control unit, the first surface of first glass plate is provided with first Polarizer, first glass plate second surface of first Polarizer dorsad is provided with an ITO conductive layer, the first surface of second glass plate is provided with second Polarizer, first Polarizer is vertical with the polarization direction of second Polarizer, and second glass plate second surface of second Polarizer dorsad is provided with the 2nd ITO conductive layer, described the 2nd ITO conductive layer comprises a plurality of ITO electrodes of uniformly-spaced arranging and is arranged at insulation secret note between the adjacent ITO electrode, described liquid crystal layer is located between an ITO conductive layer and the 2nd ITO conductive layer, described control unit is used for controlling according to control signal the on/off of alternating voltage between an ITO conductive layer and each ITO electrode, make the light and shade fringe position generation adaptive change of dynamic raster adapt to the position of human eye, make to reenter on the display pixel that is mapped to display after the printing opacity gap transmission of light incide dynamic raster, and then make left eye pixel image light incide people's left eye via dynamic raster, right eye pixel image light incides people's right eye.

Wherein, described control unit is used for the on/off of alternating voltage between an every ITO electrode of independent control and the ITO conductive layer.

Wherein, the described second glass plate a plurality of ITO electrodes on the second surface of second Polarizer dorsad is provided with TFT electrode corresponding one by one with it and that be electrically connected, the closure of described control unit by control TFT electrode/disconnect and then the control on/off of alternating voltage between a corresponding ITO electrode and the ITO conductive layer.

Wherein, described a plurality of ITO electrode of uniformly-spaced arranging comprises first group of ITO electrode and second group of ITO electrode of alternately arranging, described first group of ITO electrode comprises that N(wherein, N 〉=2, N is a natural number) individual ITO electrode, described second group of ITO electrode comprises that M(wherein, M 〉=2, M is a natural number) individual ITO electrode, all the 1st ITO electrodes are electrically connected to the same output of control unit in first group of ITO electrode, all the 2nd ITO electrodes are electrically connected to the same output of control unit in first group of ITO electrode, all N ITO electrodes are electrically connected to the same output of control unit in first group of ITO electrode, and all the 1st ITO electrodes are electrically connected to the same output of control unit in second group of ITO electrode, all the 2nd ITO electrodes are electrically connected to the same output of control unit in second group of ITO electrode, all M ITO electrodes are electrically connected to the same output of control unit in second group of ITO electrode.

Wherein, described second glass plate further is provided with a plurality of TFT electrodes on the second surface of second Polarizer dorsad, all the 1st ITO electrodes are electrically connected to the output of same TFT electrode in described first group of ITO electrode, all the 2nd ITO electrodes are electrically connected to the output of same TFT electrode in first group of ITO electrode, all N ITO electrodes are electrically connected to the output of same TFT electrode in first group of ITO electrode, all the 1st ITO electrodes are electrically connected to the output of same TFT electrode in second group of ITO electrode, all the 2nd ITO electrodes are electrically connected to the output of same TFT electrode in second group of ITO electrode, all M ITO electrodes are electrically connected to the output of same TFT electrode in second group of ITO electrode, described control unit by independent each TFT electrode of control closure/disconnections so that control the on/off of alternating voltage between a TIO bus district and the ITO conductive layer.

Wherein, a described ITO conductive layer and ITO electrode comprise indium tin metal oxide.

Wherein, the width of each described ITO electrode is a, and the width of the insulation secret note between adjacent two ITO electrodes is b, a 〉=5b.

The beneficial effects of the utility model are: the situation that is different from prior art, 3 d display device of the present utility model utilizes camera to follow the trail of the human eye positional information, and then utilize control unit to realize that according to position of human eye information the change of stop position is to adapt to two different observation places of people, the effect that the realization bore hole is watched 3D rendering.

Description of drawings

Fig. 1 is the easy structure schematic diagram of an embodiment of 3 d display device of the present utility model;

Fig. 2 is the electrical block diagram of Fig. 1 Stereo display device;

Fig. 3 is the structural representation of an embodiment of dynamic raster in the 3 d display device of the present utility model;

Fig. 4 is the electrode of ITO conductive layer of dynamic raster 14 shown in Figure 3 and the 2nd ITO conductive layer schematic diagram of arranging;

Fig. 5 is first kind of ITO telegraph circuit connection diagram of dynamic raster 14 shown in Figure 3;

Fig. 6 is second kind of ITO telegraph circuit connection diagram of dynamic raster 14 among Fig. 3;

Fig. 7 A-Fig. 7 C is that grating light and shade striped moves with human eye and the schematic diagram of the example that occurrence positions changes in the 3 d display device of the present utility model.

Embodiment

See also Fig. 1 and Fig. 2, Fig. 1 is the easy structure schematic diagram of an embodiment of 3 d display device of the present utility model, and Fig. 2 is the electrical block diagram of Fig. 1 Stereo display device.As shown in Figure 1,3 d display device 10 of the present utility model comprises: display 11, camera 12 and processor 13(diagram are seen Fig. 2).

As shown in Figure 2, camera 12 is arranged on the front end face of display 11, is used to follow the trail of the human eye positional information; Processor 13 is electrically connected with camera 12, and processor 13 receives the position of human eye information of camera 12 transmissions and generates control signal according to position of human eye information; Display 11 comprises dynamic raster 14, dynamic raster 14 is electrically connected with processor 13, dynamic raster 14 receive described control signals and according to the position of control signal control light and shade striped to adapt to the position of human eye, make the left eye pixel image light of display incide the right eye that people's left eye, right eye pixel image light incide the people.

See also Fig. 3, Fig. 3 is the structural representation of an embodiment of dynamic raster in the 3 d display device of the present utility model.As shown in Figure 3, the dynamic raster 14 of present embodiment comprises: first glass plate 141, liquid crystal layer 143, second glass plate 145 and control unit 146(are not shown).The first surface of first glass plate 141 is provided with first Polarizer (not shown), and first glass plate 141 second surface of first Polarizer dorsad is provided with an ITO conductive layer 142; The first surface of second glass plate 145 is provided with second Polarizer (not shown), first Polarizer is vertical with the polarization direction of second Polarizer, second glass plate 145 second surface of second Polarizer dorsad is provided with the 2nd ITO conductive layer 144, the two ITO conductive layers 144 and comprises many ITO electrodes of equidistantly arranging 1441 and be arranged at two insulation secret notes (sign) between the adjacent ITO electrode 1441; Wherein, liquid crystal layer 143 is located between an ITO conductive layer 142 and the 2nd ITO conductive layer 144; Control unit 146 is used for controlling according to control signal the break-make of alternating voltage between an ITO conductive layer 142 and each ITO electrode 1441, make and to reenter on the display pixel that is mapped to display after the printing opacity gap transmission of light incide dynamic raster 14 via dynamic raster, and then make left eye pixel image light incide the right eye that people's left eye, right eye pixel image light incide the people, because there is parallax in the image that people's eyes receive, thereby the right and left eyes image is through the effect of the synthetic 3D rendering of human brain.Wherein, an ITO conductive layer 142 and the 2nd ITO conductive layer 144 all are transparent conductive films.

See also Fig. 4, Fig. 4 is the electrode of ITO conductive layer of dynamic raster 14 shown in Figure 3 and the 2nd ITO conductive layer schematic diagram of arranging.As shown in Figure 4, an ITO conductive layer 142 conducts electricity entirely, and the 2nd ITO conductive layer 144 comprises the ITO electrode 1441 of a plurality of equidistant arrangements.The concrete number of ITO electrode 1441 is much larger than the number shown in Fig. 4, and the utility model does not limit this.Wherein, an ITO conductive layer 142 and ITO electrode 1441 preferably include indium tin metal oxide, but also can substitute with other electric conducting material, and this is not limited.In embodiment of the present utility model, the width of each ITO electrode 1441 is a, and the insulation secret note width between the adjacent ITO electrode 1441 is b, wherein, and a 〉=5b.In the specific design of dynamic raster of the present utility model, preferred a＞＞5b.

See also Fig. 5, Fig. 5 is first kind of ITO telegraph circuit connection diagram of dynamic raster 14 shown in Figure 3.As shown in Figure 5, an ITO conductive layer 142 is electrically connected with control unit 146, and each ITO electrode 1441 is connected on the control unit 146 by lead independently respectively.When control unit 146 is controlled corresponding switch closure independently according to control signal, make win ITO conductive layer 142 and corresponding ITO electrode 1441(and respective switch at the ITO electrode 1441 on the same circuit) between be added with alternating voltage and then form AC field, corresponding liquid crystal molecule points under effect of electric field and vows reversing of 90 degree taken place in a described ITO conductive layer 142 and the corresponding ITO electrode 1441 folded liquid crystal layers of establishing 143, the feasible change that the polarization direction takes place via the effect of liquid crystal molecule through the first polarization light of the first Polarizer incident, and then through the second Polarizer outgoing, and show as bright fringe.When control unit 146 according to control signal control chart 5 in corresponding switch when disconnecting, added alternating voltage circuit disconnects between the one ITO conductive layer 142 and the corresponding ITO electrode 1441, the sensing of corresponding liquid crystal molecule is vowed not change and is reversed in a described ITO conductive layer 142 and the corresponding ITO electrode 1441 folded liquid crystal layers of establishing 143, make and the change of polarization direction does not take place via the effect of liquid crystal molecule through the first polarization light of the first Polarizer incident, and then stopped, and show as dark fringe by second Polarizer.Utilize the break-make of alternating voltage between control unit 146 control different I TO electrodes 1441 and the ITO conductive layer 142, can realize the width light and shade width of fringe of light and shade striped of grating and/or the change of position.

Equally, in 3 d display device of the present utility model dynamic raster another embodiment in, on the circuit among Fig. 5 between ITO electrode 1441 and the control unit 146 the TFT electrode can also be set, be specially: the TFT electrode is arranged at second glass plate dorsad on the second surface of second Polarizer and corresponding one by one with the ITO electrode and be electrically connected.In this case, after the control unit 146 control TFT electrode closures, be added with alternating voltage between an ITO electrode 1441 and the ITO conductive layer 142, and after control unit 146 control TFT electrodes disconnect, be not added with alternating voltage between an ITO electrode 1441 and the ITO conductive layer 142, and then make control unit 146 realize the on/off of alternating voltage between a control ITO electrode 1441 and the ITO conductive layer 142 indirectly by the closure/disconnection of control TFT electrode.

See also Fig. 6, Fig. 6 is second kind of ITO telegraph circuit connection diagram of dynamic raster among Fig. 3.As shown in Figure 6, in a preferred embodiment of the utility model dynamic raster, the ITO electrode of described a plurality of equidistant arrangements comprises first group of ITO electrode and second group of ITO electrode of alternately arranging, described first group of ITO electrode comprises that N(wherein, N 〉=2, N is a natural number) individual ITO electrode 1441, described second group of ITO electrode comprises that M(wherein, M 〉=2, M is a natural number) individual ITO electrode 1441, all the 1st ITO electrodes 1441 are electrically connected in first group of ITO electrode, all the 2nd ITO electrodes 1441 are electrically connected in first group of ITO electrode, all N bar ITO electrodes 1441 are electrically connected in first group of ITO electrode, and all the 1st ITO electrodes 1441 are electrically connected in second group of ITO electrode, all the 2nd ITO electrodes 1441 are electrically connected in second group of ITO electrode 1441, all M bar ITO electrodes 1441 are electrically connected in second group of ITO electrode.Particularly, can be referring to shown in Figure 6, for example M and N are 5, a control voltage output end of control unit 146 can be controlled the break-make of alternating voltage between a plurality of ITO electrodes 1441 and the ITO conductive layer 142 simultaneously, and then realize that liquid crystal molecule points to the variation of vowing, so just can realize the change of grating light and shade fringe position.

In another one embodiment of the present utility model, second glass plate can further be provided with a plurality of TFT electrodes on the second surface of second Polarizer dorsad, make that by design second kind of TIO telegraph circuit connected mode of dynamic raster 14 further shows as among Fig. 6: all the 1st ITO electrodes are electrically connected to the output of same TFT electrode in first group of ITO electrode, all the 2nd ITO electrodes are electrically connected to the output of same TFT electrode in first group of ITO electrode, all N ITO electrodes are electrically connected to the output of same TFT electrode in first group of ITO electrode, and all the 1st ITO electrodes are electrically connected to the output of same TFT electrode in second group of ITO electrode, all the 2nd ITO electrodes are electrically connected to the output of same TFT electrode in second group of ITO electrode, all M ITO electrodes are electrically connected to the output of same TFT electrode in second group of ITO electrode.So, control unit 146 is by the closure/disconnection of independent each TFT electrode of control, and then realization is controlled the on/off of alternating voltage between a TIO bus district and the ITO conductive layer 142, the final adaptations that realizes light and shade fringe position in the control dynamic raster.

The positional information that 3 d display device 10 of the present utility model utilizes camera 12 to follow the trail of human eye changes according to the change of position of human eye to realize dynamic raster, and then but extensive angle realizes the effect of 3 d display device 10 3D Glassless of the present utility model, specifically please refer to Fig. 7 A-Fig. 7 C, Fig. 7 A-Fig. 7 C is that grating light and shade striped moves with human eye and a example schematic that occurrence positions changes in the 3 d display device of the present utility model.Among 7A-Fig. 7 C, the cycle of the light and shade striped of grating equals the liquid crystal region width summation that 1-6 identifies.

Shown in Fig. 7 A, camera 12 picks up human eye and is on display screen and the grating center line, processor 13 is accepted and handles to instruct after the positional information of human eye control unit 146 controls 1 and 6 liquid crystal regions that identified to show as the liquid crystal region that bright fringe, 2-5 identify under the effect of AC field not show as dark fringe owing to adding AC field, and then makes human eye can watch the image and then the formation 3D rendering effect of the left and right sides form that display screen shows.In Fig. 7 A, the part that 1-6 identified is a light and shade fringe period (as K1 or the pointed liquid crystal region width of K2), and wherein, the blank parts between the liquid crystal molecule zone that adjacent numeral identified is the part that the black insulation strip is blocked.Certainly, in concrete application of the present utility model, the cycle of light and shade striped is not limited to K1 or the pointed liquid crystal region width of K2 among Fig. 7 A-Fig. 7 C.

Shown in Fig. 7 B, when human eye moves right first position shown in Fig. 7 B, under the control of control unit 146, K1 or the K2 ITO electrode width that moves right, the light and shade striped general performance that is specially the one-period among Fig. 7 A is the ITO electrode width that moves right, 1 and the 2 liquid crystal molecule zones that identified show as bright fringe, and the liquid crystal molecule zone that 4-6 identified shows as dark fringe.When certainly human eye further moved right second definite position, under the control of control unit 146, K1 or K2 were with respect to Fig. 7 A two ITO electrode widths that move right.Certainly along with human eye continue move right, K1 or K2 are with respect to Fig. 7 A more a plurality of ITO electrode widths that move right, this need decide according to the distance of determining that human eye moves.

Shown in Fig. 7 C, when human eye is moved to the left to position shown in Fig. 7 C, K1 or K2 are moved to the left an ITO electrode width, the light and shade striped integral body that is specially the one-period among Fig. 7 A is moved to the left an ITO electrode width, the liquid crystal molecule zone that 5-6 identified shows as bright fringe, and the liquid crystal molecule zone that 1-4 identified shows as dark fringe.Wherein, among Fig. 7 A-Fig. 7 C, in the dynamic raster light and shade striped of one-period to the right or the concrete distance that moves right decide on the position of human eye.

By the way, the beneficial effects of the utility model are: 3 d display device of the present utility model utilizes camera to follow the trail of the human eye positional information, and then utilize control unit to realize that according to position of human eye information the change of stop position is to adapt to two different observation places of people, the effect that 3D rendering is watched in realization.

The above only is embodiment of the present utility model; be not so limit claim of the present utility model; every equivalent structure or equivalent flow process conversion that utilizes the utility model specification and accompanying drawing content to be done; or directly or indirectly be used in other relevant technical fields, all in like manner be included in the scope of patent protection of the present utility model.

Claims

1. 3 d display device, described 3 d display device comprises:

Display;

2. 3 d display device according to claim 1 is characterized in that, described control unit is used for the on/off of alternating voltage between an every ITO electrode of independent control and the ITO conductive layer.

3. 3 d display device according to claim 2, it is characterized in that, the described second glass plate a plurality of ITO electrodes on the second surface of second Polarizer dorsad is provided with TFT electrode corresponding one by one with it and that be electrically connected, the closure of described control unit by control TFT electrode/disconnect and then the control on/off of alternating voltage between a corresponding ITO electrode and the ITO conductive layer.

4. 3 d display device according to claim 1, it is characterized in that, described a plurality of ITO electrode of uniformly-spaced arranging comprises first group of ITO electrode and second group of ITO electrode of alternately arranging, described first group of ITO electrode comprises that N(wherein, N 〉=2, N is a natural number) individual ITO electrode, described second group of ITO electrode comprises that M(wherein, M 〉=2, M is a natural number) individual ITO electrode, all the 1st ITO electrodes are electrically connected to the same output of control unit in first group of ITO electrode, all the 2nd ITO electrodes are electrically connected to the same output of control unit in first group of ITO electrode, all N ITO electrodes are electrically connected to the same output of control unit in first group of ITO electrode, and all the 1st ITO electrodes are electrically connected to the same output of control unit in second group of ITO electrode, all the 2nd ITO electrodes are electrically connected to the same output of control unit in second group of ITO electrode, all M ITO electrodes are electrically connected to the same output of control unit in second group of ITO electrode.

5. 3 d display device according to claim 4, it is characterized in that, described second glass plate further is provided with a plurality of TFT electrodes on the second surface of second Polarizer dorsad, all the 1st ITO electrodes are electrically connected to the output of same TFT electrode in described first group of ITO electrode, all the 2nd ITO electrodes are electrically connected to the output of same TFT electrode in first group of ITO electrode, all N ITO electrodes are electrically connected to the output of same TFT electrode in first group of ITO electrode, all the 1st ITO electrodes are electrically connected to the output of same TFT electrode in second group of ITO electrode, all the 2nd ITO electrodes are electrically connected to the output of same TFT electrode in second group of ITO electrode, all M ITO electrodes are electrically connected to the output of same TFT electrode in second group of ITO electrode, described control unit by independent each TFT electrode of control closure/disconnections so that control the on/off of alternating voltage between a TIO bus district and the ITO conductive layer.

6. 3 d display device according to claim 1 is characterized in that, a described ITO conductive layer and ITO electrode comprise indium tin metal oxide.

7. 3 d display device according to claim 1 is characterized in that, the width of each described ITO electrode is a, and the width of the insulation secret note between adjacent two ITO electrodes is b, a 〉=5b.